# -*- encoding=utf-8 -*-
#*************************************************************************
#  Copyright (C) 2019 by Robert Caulk and Bruno Chareyre                 *
#  rob.caulk@gmail.com                                                   *
#                                                                        *
#  This program is free software; it is licensed under the terms of the  *
#  GNU General Public License v2 or later. See file LICENSE for details. *
#*************************************************************************/

## Example script showing the use of alpha boundary for flowengine applications ##

from yade import pack, ymport, export
from yade import timing
import numpy as np
import shutil
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d import Axes3D

timeStr = time.strftime('%m-%d-%Y')

identifier = 'testingAlpha'

if not os.path.exists('VTK' + timeStr + identifier):
	os.mkdir('VTK' + timeStr + identifier)
else:
	shutil.rmtree('VTK' + timeStr + identifier)
	os.mkdir('VTK' + timeStr + identifier)

mx = Vector3(0.9639118565206523, 0.9324110610237126, 0.8800533096533549)
mn = Vector3(-0.9518976876470108, -0.9685168132064216, -0.9451956043076566)

walls = aabbWalls([mn, mx], thickness=0)
wallIds = O.bodies.append(walls)

pred = pack.inSphere(Vector3(0, 0, 0), 1)
sp = pack.randomDensePack(pred, radius=0.1, rRelFuzz=0.1, returnSpherePack=False, seed=1)
O.bodies.append(sp)

O.engines = O.engines[0:3] + [FlowEngine(dead=0, label="flow", multithread=False)] + O.engines[3:5]


# visualization of the alpha boundary: filter cells by "alpha" in paraview
def pressureField():
	flow.saveVtk('VTK' + timeStr + identifier + '/', withBoundaries=False)


O.engines = O.engines + [PyRunner(iterPeriod=100, command='pressureField()', dead=0)]

for b in O.bodies:
	if isinstance(b.shape, Sphere):
		b.dynamic = False

flow.defTolerance = -1
flow.meshUpdateInterval = -1
flow.useSolver = 4
flow.permeabilityFactor = -1e-1
flow.alphaBound = 0.3  # using manual alpha. Selecting a value of 0 will let CGAL find the minimum alpha necessary for obtaining a solid. Any positive value will be used as a manual alpha.
flow.alphaBoundValue = 0  # the pressure to assign to the boundary
flow.fixedAlpha = 0  # if false, use logic to improve concavity cell volume.
flow.imposePressure((0, 0, 0), 1)

O.dt = 1e-6
O.dynDt = False

O.run(101, 1)

flow.printVertices()

dat = np.loadtxt('vertices.txt', skiprows=1)
xs = dat[7:, 1]
ys = dat[7:, 2]
zs = dat[7:, 3]

radii = dat[7:, 4]
alpha = dat[7:, 5]

fig = plt.figure()
ax = fig.add_subplot(111, projection='3d')

ax.scatter(xs, ys, zs, c=alpha)  # plot the alpha vertices as yellow

plt.show()
